The practical computational and analytic modeling of stochastic
fluid flow is a demanding challenge. We review several separate
components of an integrated approach to this problem, drawing on
recent results of the speaker, colleagues, and others.

Stochastic risk assessment of engineering systems motivates
this study, as it requires stochastic fluid flow as an input.
The use of multiple simulations to evaluate a stochastic ensemble places a
strong premium on fast algorithms. Upscaling is a necessary approach
to achieving fast algorithms in many cases. Upscaling can be understood
as the opposite of multigrid methods in a multiscale problem:
Finely gridded data is used to condition a coarsely gridded solution.
Analytic, numerical, and experimental studies are needed to validate
upscaling methodologies. Massively parallel computing based on a
locally-assembled supercomputer with commodity components and public
domain software is a cost effective solution for the still remaining
large computational problems.

In combination, these methods appear to be capable of solving
previously intractible stochastic fluid flow problems.